Printable coating

ABSTRACT

A primer-less coating composition for facestock comprises: a binder being a water-dispersible polymer; an ethylenically unsaturated compound which is aqueous-dispersible and miscible with or bonded to said water-dispersible polymer, wherein said ethylenically unsaturated compound is able to form a covalent bond with an ink; and a crosslinker, wherein said crosslinker is suitable for binding the coating to the facestock. The coating composition may be applied to a substrate to form a printable film. A printed film in accordance with the invention may be used in a label, for example for use on a container such as a bottle.

This application is a Continuation Application of U.S. application Ser.No. 13/128,536 filed on May 10, 2011, which is a National StageApplication of PCT/GB2009/051670 filed on Dec. 8, 2009, which claimspriority from United Kingdom Patent Application No. 0822412.3, filed onDec. 9, 2008. The entirety of all of the aforementioned applications isincorporated herein by reference.

FIELD

The present invention relates to an improved coating to which print canbe applied. In particular, though not exclusively, the present inventionrelates to an improved printable film having good adhesive propertieswhen used with radiation curable ink.

BACKGROUND

In recent years, diversification of printed products has requiredprinting on a wider variety of materials in sheets; for example, papers,synthetic papers, polymer films such as thermoplastic resin films,metallic foils, metallized sheets, etc. These printed items are printedby methods such as by offset printing, gravure, flexography, screenprocess printing and letterpress printing. In these printing methods, amethod which uses radiation curable ink has recently become popularbecause radiation curable inks cure rapidly, and the printing methodwhich uses radiation curable ink is of superior handling. Radiationcurable inks are known to be useful in the printing of packaging, labelsand non absorbing printing materials. Radiation curable printing inkstypically contain unsaturated acrylates, polyesters, photoinitiators,and additives. In electron beam cured inks however, the photoinitiatorsmay be omitted.

After deposition of the radiation curable ink on the printable item, theprint is exposed to radiation and hardens within a fraction of a second.Printing speeds up to 300 m/min are attained during continuous printing.At present, there is a great demand for sheet-like printable items.

In printing methods, the printing sheet desirably has good sheet runningproperties and anti-blocking properties, producing uniform spread of theink over the surface of the sheet, as well as antistatic properties.Besides these generally required properties, in printing methods whichuse radiation curable ink, the printing sheet requires in particular theproperty of adhering strongly to radiation cured ink.

In particular, radiation curable ink printed polymer films, intended foruse as labels, for example in the bottle labelling market, should beresistant to both freezing water conditions (to allow storage of theresultant product in coolers or ice buckets) and sterilization processesfor example by exposure to steam (to ensure pre-labelled bottles are fitfor filling).

European patent application EP-A1-410051 discloses printing sheetscomprising a support layer and a surface layer on at least one face ofsaid support, said surface layer containing at least an acrylate basedpolymer and an unsaturated compound (cinnamic acid or derivativesthereof). This document does not teach anything about the possibility ofuse of other monomers to replace cinnamic acid.

WO-A-02/048260 discloses what are said to be improved binders,ink-receptive compositions and coated substrates containing a binder, aparticulate filler and a mordant. Preferred binders include one or moreacrylic copolymers made with at least one wet abrasionresistance-enhancing monomer. The coating compositions disclosed thereinare fully saturated, with ink receptivity being provided by the mordantand/or the filler.

WO-A-01/60878 discloses co-mingled polyurethane-polyvinyl estercompositions for use as coatings intended for protectivity rather thanink receptivity. This document suggests the use of a water-dispersibleUV-hybrid coating which is fully cured during the manufacturing process.

US 2002/0098340 discloses a printable film comprising a substrate and atleast a surface layer which covers at least one face of the substrateand which comprises a water dispersible polymer and an ethylenicallyunsaturated compound. However said product can be expensive andcomplicated to produce due to its multi-component nature. This documentteaches the use of primers intermediate between the substrate and thesurface layer to provide a satisfactory level of adherence.

However, the above listed materials formed in sheets, especially polymerfilms, do not sufficiently adhere to radiation curable ink afterprinting and curing, especially in these extreme conditions. Accordinglythe printed and radiation cured ink is problematic in that the printedand radiation cured ink separates from the polymer film.

Improvements are required in the area of printable films, in order toachieve a product which is cost-effective, easy to manufacture, andwhich also has appropriate adhesion properties.

SUMMARY

From a first aspect the present invention provides a primer-less coatingfor facestock, comprising: a binder being a water-dispersible polymer;an ethylenically unsaturated compound which is aqueous-dispersible andmiscible with or bonded to said water-dispersible polymer, wherein saidethylenically unsaturated compound is able to form a covalent bond withan ink; and a crosslinker, wherein said crosslinker is suitable forbinding the coating to the facestock.

Suitable substrates, which can be used in this invention as thefacestock, are polymer films, especially polyolefin films, papers,synthetic papers, woven fabrics, nonwoven fabrics, ceramic sheets,metallic fiber sheets, metallized sheets, metallized films, metallicfoils, metallic plates, and multilayer composite sheets formed bycombination of said materials. For printable film intended for use aslabels, polyolefin films are preferred, especially orientedpolypropylene films, and still more preferred is an orientedpolypropylene film according to EP-A-0202812.

The printable films referred to herein are films which can be directlyinked, i.e. a film of which the surface layer is strong enough to resistthe pull of the tacky ink, otherwise areas of the surface layer may bepulled away from the surface, giving a defect known as picking.

The coating formulation, resultant coating, and coated products do notcomprise a primer. This gives advantages not only in terms of cost butalso in terms of production equipment and simplicity. Furthermore, theprimer-less systems allow improved printability. The considerable volumeof prior art disclosing primers teaches away from the primer-less systemof the present application.

In some prior art systems an open printable surface is provided by aninteraction between a polymer (for example an acrylic polymer) and anethylenically unsaturated compound (for example EBECRYL® (EthoxylatedTMPTA) from Cytec Industries Inc.). When the film is printed the wet inkadheres to the coated surface and then, when the printed film isradiation-cured, the UV initiators (contained in the ink) start aradical curing reaction which cross-links EBECRYL® with itself and theink and thus binds the ink on the surface of the film. The skilledperson has typically avoided using crosslinkers for the purpose ofbinding the coating to the film, because of the fear of giving rise to ahard, unprintable film; instead a separate primer layer has usually beenused in prior art systems between the film and the coating for thepurpose of binding the film to the coating.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 shows an example of a coated film in accordance with the presentinvention.

DETAILED DESCRIPTION

Surprisingly the present inventors have found that a crosslinker can beused in the coating formulation in order to effect the binding, withoutcompromising other qualities such as good printability. The presentinventors have found that a crosslinker can be used to bind functionalgroups on the film surface with functional groups in the components ofthe coating composition. The crosslinker also provides the film withwater-resistance without excessively hardening the product, therebymeaning that the surface can still be readily printed. In fact,improvements in printability are seen.

The crosslinker is used such that it can provide effective adhesion (andoptionally also water resistance) whilst also resulting in effectiveprintability. Non-isocyanate crosslinkers are preferred, because theinventors have found that isocyanate can self-crosslink to give a hard,print-resistant, polyurea component. The inventors have obtained goodresults with carbodiimide and especially aziridine crosslinkers andtherefore these crosslinkers are preferred. The skilled person willappreciate that other crosslinkers, which provide the binding effect andresult in effective printability, are also within the scope of thepresent invention.

The system of the present invention can again be contrasted withprimer-based systems of the prior art, wherein a bond is formed by meansof the separate primer layer which is present only at the interfacebetween the film and the topcoat and is not present in the topcoatitself.

In the present invention the cross-linker is typically able to reactwith the ethylenically unsaturated compound, which may or may not formpart of and/or be pendant from, the backbone of the water dispersiblepolymer. Optionally the chemical interaction is a three-way interactionincluding these two materials and also the polymer, thereby effectivelyforming a pre-polymer on the film surface for the reception of ink andsubsequent curing by the radiation cure.

Furthermore, the cross-linker is typically present in the coatingcomposition in an amount in excess of that required for stoichiometriccross-linking of the water-dispersible polymer. This enables there to besome crosslinker left available to react with the ethylenicallyunsaturated compound.

In the primerless system of the present invention, the crosslinker ispreferably present throughout the coating. The crosslinker preferablyreaches from the film (substrate) where it binds to functional groupsthereon (for example, acid, hydroxyl and amino groups thereon), all theway through the topcoat where it crosslinks the polymer and interactschemically with the ethylenically unsaturated compound, to the surfacewhere it locks in the ethylenically unsaturated compound and yet leavesfunctional groups available on the ethylenically unsaturated compound tobind the ink. It is a key feature of the present invention that theethylenically unsaturated compound present in the system retain at leastsome of its unsaturation at the point at which ink is applied to thesystem. In other words, the coating comprises an ethylenicallyunsaturated compound which is not cured to any extent that would fullyremove ethylenic unsaturation from the compound and prevent its bindingto an ink applied to the coating surface. The ethylenically unsaturatedcompound used in the coating formulation of the invention must have thecapacity (through one or more of its ethylenically unsaturated groups)to bind to an ink applied to the coating. In other words, theethylenically unsaturated compound forms a covalent bond with an ink byvirtue of ethylenically unsaturated groups extant in the coating at thetime an ink is applied thereto. A coating formulation originallyformulated with an ethylenically unsaturated compound but then curedprior to inking such that insufficient ethylenically unsaturated groupsfor ink adhesion remain in the coating will not be in accordance withthe invention.

The combination of components is such that excess crosslinker can beused without resulting in over cross-linked, hard unprintable film. Somepreferred crosslinkers are able to avoid the disadvantages of excesscross-linking by hydrolyzing instead. The following can also play arole, and can be varied by the skilled person accordingly: the reactionwith the ethylenically unsaturated compound; the three-way interactiontaking into account the polymer; the particular functionality of thematerials including for example a limited level of acid functionality inthe polymer make-up; the amount of crosslinker; and the monomers chosenwhen performing the original polymerization.

The mechanism of the chemical interaction between the crosslinker andthe ethylenically unsaturated compound may optionally be a base inducednucleophilic addition reaction across the unsaturated (ethylenic) bond,for example a Michael addition or alternatively/additionally aBaylis-Hillman Reaction.

The coating composition is preferably an aqueous-based composition;alternatively a solvent (for example MEK—methyl ethyl ketone—orisopropyl acetate) based system can be used. Organic solvent-basedsystems may optionally be used in combination with polyester binders,and/or aromatic crosslinkers.

The ethylenically unsaturated compound is preferably dispersible ormiscible (as opposed to soluble) in water.

The coating of the present invention may form a layer which covers atleast one face of the substrate listed above. The water-dispersiblepolymer may by way of non-limiting example be selected from waterdispersible acrylates, urethanes, urethane acrylates, styrenebutadiene/maleic anhydride copolymers and mixtures thereof. The waterdispersible polymer forms a smooth, film-formed and ink-receptivesurface.

Acrylic polymers used as the water dispersible polymer include(co)polymers obtained by the free-radical addition polymerization of atleast one (meth)acrylic type monomer and optionally of other vinylic orallelic compounds. The acrylic polymers provide a smooth film-formed andink-receptive surface.

A wide variety of acrylic polymers are able to fulfill this requirement.Suitable acrylic polymers are homopolymers of (meth)acrylic acid oralkyl(meth)acrylate, the alkyl radical having 1 to 10 carbon atom, orcopolymers of two or more of the said (meth)acrylic type monomer andoptionally of other vinylic or allylic compounds.

As stated above, a water dispersible urethane polymer may also suitablybe used. As with the acrylic polymer, it is essential that this urethanepolymer should be able to provide a smooth film-formed and ink-receptivesurface.

A wide variety of urethane polymers are able to fulfill thisrequirement. Suitable urethane polymers are for example the reactionproduct of an isocyanate-terminated polyurethane prepolymer formed byreacting at least an excess of an organic polyisocyanate, an organiccompound containing at least two isocyanate-reactive groups and anisocyanate-reactive compound containing anionic salt functional groups(or acid groups which may be subsequently converted to such anionic saltgroups) or non-ionic groups and an active hydrogen-containing chainextender.

The water dispersible polymer has sufficiently low levels of reactivefunctional groups to limit the cross-link density in order to providesufficient water resistance for finished film properties whilst leavinga surface which is receptive to printing inks, said inks beingUV-curable, water based or solvent based. Preferably there is less than10 weight % of reactive functional groups.

The amount of water dispersible polymer is for example 10 to 98%,preferably 60-95%, more preferably 74-92% in terms of the weight afterdrying of the coating composition.

The surface layer comprises also an ethylenically unsaturated compound.

The ethylenically unsaturated compound is selected to be miscible in thewet stage in the aqueous phase and to be compatible in the dry stagewith the water dispersible polymer itself. Consequently, theethylenically unsaturated compound acts as a plasticiser for the surfacelayer once hardened allowing the easy penetration of the radiationcurable ink thereto. Alternatively, or as well, the ethylenicallyunsaturated compound may be provided as part of the water dispersiblepolymer itself—for example as a functional side chain thereof.

The ethylenically unsaturated compound must also be able, when theprinted film is submitted to radiation in order to cure the ink, toreact with the unsaturated components of the ink which have penetratedinto the surface layer.

This reaction between the ethylenically unsaturated compounds of thesurface layer and the unsaturated compounds of the radiation curable inkforms chemical bonds between those compounds and simultaneouslycrosslinks the surface layer, thereby generating the final resistantproduct.

Preferably, the ethylenically unsaturated compound contains 1 to 10double bonds per molecule and still more preferably 2 to 5 double bondsper molecule (or per functional group in the event that the compound isprovided as a pendant side chain from, or otherwise as part of, thewater dispersible polymer).

Suitable ethylenically unsaturated compounds are the ester derivativesof [alpha], [beta]-ethylenically unsaturated acids, such as acrylic ormethacrylic acids, itaconic or citraconic acids, maleic or fumaricacids, etc. with polyols or alkoxylated polyols. Other suitableethylenically unsaturated compounds include derivatives of isocyanateprepolymers or oligomers reacted with ethylenically unsaturated alcoholsand ethoxylated variants thereof, such as Desmodur (Bayer) trifunctionalisocyanate reacted with hydroxyl ethyl methacrylate. In other words,ethylenically unsaturated compounds used in accordance with theinvention may contain one or more urethane linkages in addition to, orinstead of, one or more ester linkages.

The suitable polyols include saturated aliphatic diols such as ethyleneglycol, diethylene glycol, triethylene glycol, propylene glycol,dipropylene glycol, tripropylene glycol, butylene glycols, neopentylglycol, 1,3- and 1,4-butane diols, 1,5-pentane diol, 1,6-hexanediol and2-methyl-1,3 propanediol. Glycerol, 1,1,1-trimethylolpropane, bisphenolA and its hydrogenated derivatives may also be used. The suitablealkoxylated polyols include the ethoxylated or propoxylated derivativesof the polyols listed above.

Examples of ethylenically unsaturated compounds which can be usedaccording to the invention are polyfunctional acrylates such asdifunctional acrylates, such as 1,4-butane diol diacrylate, 1,6-hexanediol diacrylate, neopentyl glycol diacrylate, triethylene glycoldiacrylate, polyethylene glycol diacrylate, tripropylene glycoldiacrylate, 2,2-dionol diacrylate, bisphenol A diacrylate, etc.,trifunctional acrylates such as pentaerythritol triacrylate,trimethylolpropane triacrylate, etc., tetrafunctional acrylates, etc.

It is to be understood that the methacrylate derivatives correspondingto these acrylate derivatives could also be used.

Moreover, it has been found that polyallyl derivatives such astetraallyloxyethane are also suitable. Suitable materials in thisconnection are commercially available under the trade name EBECRYL® fromCytec Industries Inc.

The amount of the ethylenically unsaturated compound can for example befrom about 2 to about 90% by weight of the acrylic polymer, andpreferably is from about 2 to about 15% or 2 to 10% (in the presentspecification, all percentages are dry weight based).

Suitable cross-linking agents include carbodiimide & aziridinecrosslinkers, and cross-linkers disclosed in for example WO 02/31016.The cross-linkers can form bonds between carboxyl, hydroxyl or aminefunctional groups at the interface between the base and the topcoat.

The crosslinking agent may also improve the hardness and/or waterresistance of the surface layer deposited on the film and consequently,of the finished product, whilst resulting in a surface layer which, oncehardened, allows the easy penetration of the radiation curable inkthereto.

For example, 1-10% of crosslinker may be used, or more preferably 1-5%or 2-5%.

For example, where the polymer is an acrylic polymer, the amount of thecrosslinking agent can be up to 10% by weight of the acrylic polymer,and preferably is from 1 to 5% by weight of the acrylic polymer.

The surface layer can contain all other additional agents, if necessary,for preventing the blocking of one sheet to another, and for improvingthe sheet running property, antistatic property, non-transparencyproperty, etc. These additional agents are generally added in a totalamount not exceeding about 40% by weight of the acrylic polymer. As saidadditional agent, for example, a pigment such as polyethylene oxide,silica, silica gel, clay, talc, diatomaceous earth, calcium carbonate,calcium sulfate, barium sulfate, aluminium silicate, synthetic zeolite,alumina, zinc oxide, titanium oxide, lithopone, satin white, etc. andcationic, anionic and nonionic antistatic agents, etc. may be used.

For example, an ink adhesion promoter and surface hardener may be used,e.g. colloidal silica. An ink adhesion promoter and surface hardener mayfor example be present in an amount of 5 to 20%.

Suitable antiblock materials which may be used include silica, clays,non-film forming polymers (e.g. PMMA dispersions and beads), for examplein an addition amount of 0.1 to 3%, preferably 0.1 to 1.0%.

Water may be used to give coating solids of approximately 5 to 20%.

According to the present invention, the surface layer may be applied asan aqueous dispersion at about 0.5 to about 2.5 g/m² on the substrate bythe method of roll coating, blade coating, spray coating, air knifecoating, rod bar coating, reverse gravure, etc. on the substrate andthen dried, for example, in a hot air oven.

After the drying step, the surface layer comprises thus the waterdispersible polymer, smoothly crosslinked by the crosslinking agent and,included in the acrylic polymer matrix, the ethylenically unsaturatedcompound. This allows the easy penetration of the radiation curable inkinto the surface layer as well as its subsequent reaction with theethylenically unsaturated compound.

The present invention does not use a primer. However, before applyingthe surface layer, if sufficient functionality is not available at thesurface of the substrate, it can optionally be pretreated in aconventional manner with a view to improve wetting & adhesion. For thispurpose, it is possible, for example, to pretreat the substrate by thecorona effect, corona discharge, flame, or oxidizing chemicals, but itshould be understood that all known techniques aiming at improving thesurface of a sheet-like item with a view of the application of acomposition, may be suitable.

A reverse face of the substrate, namely a face not covered by thesurface layer, can be covered with a pressure-sensitive adhesive layerwhich consists of a commonly used pressure-sensitive adhesive agent.Furthermore, if necessary, a releasing film or sheet consisting of areleasing agent, can cover the pressure-sensitive adhesive layer. Thislaminate comprising the printing sheet according to the invention can beused as an adhesive label which may be affixed to most types of surface.In certain embodiments, the reverse face is also covered by a surfacelayer having the same coating composition as the surface layer on theother face. The surface layer on the reverse face comprises no primerlayer.

Another aspect of the invention concerns a container labeled with aprintable film according to the present invention. In one embodiment,the printable film may be used in a label, for example for use on acontainer such as a bottle. In a particular embodiment, a printable filmintended for labels comprises a substrate of which only one face iscoated with a surface layer and of which the other face is coated with apressure-sensitive adhesive layer which is itself covered with areleasing film or sheet.

Another aspect of the present invention relates to a process for themanufacture of a printable film comprising the step of coating at leastone side of a substrate with an aqueous dispersion comprising a waterdispersible polymer and an ethylenically unsaturated compound and asuitable crosslinking agent and optionally conventional additives, andcomprising further the step of drying the coating so obtained. In oneembodiment, the process further comprises the step of applying an ink tothe dried coating at a time when the coated film has been supplied on toa printing station.

The process of manufacture of a printable film may optionally comprisebefore the step of coating at least one face of the substrate, a furtherpretreatment step of the substrate (such as corona discharge treatment).

In a particular embodiment directed to the preparation of labels, onlyone face of said substrate is coated with a surface layer and the oneface-coated substrate so obtained is coated with a pressure-sensitiveadhesive or in a variant, the pressure-sensitive adhesive may betransferred from a release liner with which the coated substrate iscombined.

Another object of the present inventions concerns a printed filmcomprising a substrate of which at least one face is coated with asurface layer comprising a water dispersible polymer and anethylenically unsaturated compound and suitable crosslinker, said coatedface of the substrate being printed by conventional methods such asoffset printing, gravure, flexography, screen process printing andletterpress printing using radiation curable ink and subsequentlyradiation cured.

Ink formulations for radiation curing contains generally pigments,vehicle, solvent and additives. The solvents in these systems arelow-viscosity monomers, capable of reacting themselves (i.e., used asreactive diluents). The vehicle is usually composed of a resin derivedfrom unsaturated monomers, prepolymers or oligomers such as acrylatesderivatives which are able to react with the ethylenically unsaturatedcompound of the surface layer. For a UV ink, the “additives” contain alarge amount of photoinitiators which respond to the photons of UV lightto start the system reacting.

A UV ink formulation may be generalized as:

Pigment 15-20% Prepolymers 20-35% Vehicle 10-25% Photoinitiators  2-10%other additives   1-5%.

For an electron beam curable ink, the “additives” contain generally nophotoinitiator.

The low viscosity monomers, sometimes termed diluents, are capable ofchemical reactions which result in their becoming fully incorporatedinto the ultimate polymer matrix.

The vehicle provides the “hard resin” portion of the formulation.Typically, these are derived from synthetic resins such as for example,urethanes, epoxides, polyesters which have been modified by reactionwith compounds bearing ethylenic groups such as for instance(meth)acrylic acid, hydroxyethyl(meth)acrylate, reaction product ofcaprolactone with unsaturated compounds bearing a hydroxyl group, andthe like.

Appropriate adjustments could be made in the selection of theprepolymers and monomers used in order to achieve the requiredviscosities for the different methods of application.

Another aspect of the invention relates to a process for the manufactureof a printed film comprising the steps of

a) coating a substrate with an aqueous dispersion comprising a waterdispersible polymer and an ethylenically unsaturated compound and asuitable crosslinker;

b) drying the coating so obtained;

c) inking the dried coating with radiation-curable ink;

d) curing the ink with UV or EB radiations.

It is to be noted that the different steps of this process may beeffected in the same conditions (speed, costs, etc.) as withconventional surface layer.

Finally, the invention concerns also a printed film as obtained byinking a printable film according to the invention, and especially aprinted label so obtained.

An example of a coated film in accordance with the present invention isshown, schematically and not to scale, in FIG. 1.

EXAMPLES

The following Examples are given for the purpose of illustrating thepresent invention and may be coated onto a substrate film in accordancewith standard techniques.

The Raw materials used in these examples are sourced from the followingsuppliers: Cytec Surface Specialties S.A./N.V. Anderlechtstraat, 33,1620 Drogenbos; Alberdingk Boley GmbH Europe Headquarters, DuesseldorferStr. 53, 47829 Krefeld, Germany; Cray Valley Laporte Road,Stallingborough, North East Lincolnshire, DN41 8DR; Flevo Chemie(Nederland) B.V., Havendijk 8a, 3846 AD Harderwijk, The Netherlands;Gasil Silica INEOSSilicas Limited, Warrington, England WA5 1AB; BaxendenChemicals Ltd, Paragon Works, Worsley Street, Rising Bridge, Accrington,BB5 2SL; Bayer Material Science 100 Bayer Road, Pittsburgh, Pa. 15205;Grace Davison Oak Park Business Centre, Alington Road, Little Barford,St. Neots, Cambs PE19 6WL; NIPPON SHOKUBAI EUROPE N.V. Haven 1053,Nieuwe Weg1, B-2070 Zwijndrecht, Belgium; Nissando Industries Inc.1-2-3, Onodai Midori-ku, China; DSM NeoResins+ Sluisweg 12, PO Box 1235140 AC Waalwijk, The Netherlands.

Sample 1

Acrylic copolymer (Craymul 8500; Cray Valley) 82.8 (74.0-90.9)% Silica(Gasil HP250; Crossfield) 0.2 (0.1-1.0)% Colloidal silica (Ludox x30;GRACE Davison) 12 (5-20)% EBECRYL ® 160 (Cytec) 3 (2-10)% XAMA-7(polyfunctional aziridine crosslinker; 2 (2-5)% Bayer Polymers) Water togive coating solids of approximately 5-20%

Sample 2

Acrylic copolymer (Craymul 8405; Cray Valley) 81.5 (74.0-90.9)% Silica(Seahostar KE250; Nippon Shokubai) 0.5 (0.1-1.0)% Colloidal silica(Bindzil 15/500; GRACE Davison) 5-20% EBECRYL 160 (Cytec) 5 (2-10)% PFAZ322 (polyfunctional aziridine crosslinker; 3 (2-5)% Bayer Polymers)Water to give coating solids of approximately 5-20%

Sample 3

PU Dispersion (Witcobond 315-40; Baxenden  33% Chemicals) Acryliccopolymer (Craymul 8500; Cray Valley) 42.8 (41.0-57.9)% Silica(Seahostar KE250; Nippon Shokubai) 0.5 (0.1-1.0)% Colloidal silica(Ludox x30; GRACE Davison) 15 (5-20)% EBECRYL ® 160 (Cytec) 5 (2-10)%XAMA-2 (polyfunctional aziridine crosslinker; 3.7 (2-5)% Bayer Polymers)Water to give coating solids of approximately 5-20%

(The stated ranges in parentheses in the above samples 1 to 3 arepreferred ranges for the stated materials, and the stated numbers beforethe parentheses are specific examples of contemplated formulationswithin the suggested preferred ranges.)

The following more specific formulations in accordance with theinvention were prepared, or prepared in a form suitable for laboratorytesting in the absence of a stated antiblock component, and tested asdescribed:

Example 1

Component Dry % Description Alberdingk U3305 76.96 PU Acrylatedispersion Ludox X30 10.00 Colloidal Silica Antiblock 1.00 ParticulatePMMA Sartomer CN133 7.00 Aliphatic Oligomer Tri-acrylale Dowfax 2A1 0.04Dispersion surfactant CX 100 5.00 Aziridine Cross-linker (DSM)

Example 2

Component Dry % Description Ucecoat 7655 85.00 PU Acrylale from Cytecwith ethylenic unsaturation built on polymer backbone Ludox X30 10.00Colloidal Silica Antiblock 1.00 Particulate PMMA PZ-28 4.00 AziridineCross-linker (PolyAziridine, LLC)

Example 3

Component Dry % Description Alberdingk U3305 76.96 PU Acrylatedispersion Ludox X30 10.00 Colloidal Silica Antiblock 1.00 ParticulatePMMA Sartomer CN133 7.00 Aliphatic Oligomer Tri-acrylate Dowfax 2A1 0.04Dispersion surfactant Carbodilite E-03A 5.00 Carbodiimide Cross-linker(Nissindo Industries)

Example 4

Component Dry % Description Ucecoat 7655 64.56 PU Acrylate from Cytecwith ethylenic unsaturation built on polymer backbone Ludox X30 10.00Colloidal Silica (Grace Davidson) Antiblock 1.00 Particulate PMMA CX 1004.00 Aziridine Cross-linker (DSM) R610 20.00 PU Dispersion (DSM)

Example 5

Component Dry % Description Ucecoat 7655 77.96 PU Acrylate from Cytecwith ethylenic unsaturation built on polymer backbone Ludox X30 10.00Colloidal Silica Antiblock 1.00 Particulate PMMA CX 100 4.00 AziridineCross-linker Sartomer 454 7.00 Ethoxylated TMPTA (Sartomer) Dowfax 2A10.04 Dispersion Surfactant

Other more specific formulations contemplated in accordance with theinvention are as follows:

Example 6

Component Dry % Description Alberdingk U3305 76.96 PU Acrylatedispersion Bindzil 30/310 10.00 Colloidal Silica Antiblock 1.00Particulate PMMA EBECRYL ® 1160 7.00 Ethoxylated TMPTA (Cytec) Dowfax2A1 0.04 Dispersion surfactant CX 100 4.00 Aziridine Cross-linker

Example 7

Component Dry % Description Alberdingk U3305 76.96 PU Acrylatedispersion Bindzil 30/310 10.00 Colloidal Silica Antiblock 1.00Particulate PMMA Sartomer 454 7.00 Ethoxylated TMPTA Dowfax 2A1 0.04Dispersion surfactant Ucarlink XL29SE 5.00 Carbodiimide Cross-linker(Dow Chemicals)

The systems of these samples and examples should have a usable pot lifeof approximately 8 to 12 hours before crosslinker is consumed.Nevertheless, addition of further crosslinker revitalizes theformulation, without significant effects on the finished filmproperties.

After coating of the above specific formulations of Examples 1 to 5 ontoa film, the coated film was dried in a hot air oven and then printed ina screen printing process with commercially available UV curable screeninks, at 5 to 15 g/m². Examples are RN752 & 650-CWHD inks from FUJIFILMSERICOL, UVSF-172 ink from PARAGON INKS. RSP Series inks from NORCOTE orCombiwhite USW90004 & UVOSCREEN II™ ink from FLINT INKS.

The printed film so obtained was UV cured using typical commercialconditions UV lamp powers of 100-200 W/cm at typical press speeds of50-100 m/min.

The printed film finally obtained was tested according to followingmethod:

Exposure to extreme wet conditions at high temperature (typically >90°C.) and low temperature (0° C.) followed by immediate scratch testing.Each of Examples 1 to 5 passed the high temperature test, and Example 3passed a modified low temperature test at 4° C.

Similar results are expected in relation to each of Examples 6 and 7,and specific Examples formulated in accordance with Samples 1 to 3.

The results showed that the new primerless system of the presentinvention delivers an excellent printed film suitable for labeling in,for example, the beverage industry.

What is claimed is:
 1. A coating composition for a facestock, saidfacestock having a substrate layer, comprising: a binder being awater-dispersible polymer, wherein said water-dispersible polymer is aurethane; an ethylenically unsaturated compound which isaqueous-dispersible and miscible with said water-dispersible polymer,wherein said ethylenically unsaturated compound is able to form acovalent bond with an ink by virtue of ethylenically unsaturated groupsextant in the coating at the time an ink is applied thereto; and acrosslinker that binds to functional groups on the surface of thesubstrate and functional groups in the coating composition, includingthe ethylenically unsaturated compound, wherein said crosslinker canbind and adhere the coating composition to the facestock, wherein saidcrosslinker is present in an amount in excess of that required forstoichiometric crosslinking of the water-dispersible polymer, whereinsaid crosslinker is an aziridine crosslinker and is the only crosslinkerpresent in said coating composition, and wherein said coatingcomposition is capable of forming an ink-receptive surface suitable forprinting.
 2. The coating composition as claimed in claim 1, wherein saidethylenically unsaturated compound is present in an amount of 2 to 90%by weight after drying of the coating composition.
 3. A printable film,comprising: a substrate having two faces; and at least one surface layerformed from the coating composition as claimed in claim 1, wherein theprintable film comprises no primer layer.
 4. The printable film asclaimed in claim 3, wherein the substrate is selected from the groupconsisting of polymer films, polyolefin films, papers, synthetic papers,woven fabrics, nonwoven fabrics, ceramic sheets, metallic fiber sheets,metallized sheets, metallized films, metallic foils, metallic plates,and multilayer composite sheets formed by combinations thereof.
 5. Theprintable film as claimed in claim 3, wherein the substrate is anoriented polypropylene film.
 6. The printable film as claimed in claim3, wherein only one face of the substrate is coated with the at leastone surface layer and the other face of the substrate is covered with apressure-sensitive adhesive layer.
 7. A printed film, comprising theprintable film of claim
 3. 8. A label, comprising the printed film ofclaim
 7. 9. A labeled container, comprising the label of claim
 8. 10. Aprintable film, comprising: a substrate having two faces; a firstsurface layer, formed on one face of the substrate; and a second surfacelayer, formed on the other face of the substrate, wherein the firstsurface layer and second surface layer are formed from the coatingcomposition as claimed in claim 1, and wherein the printable filmcomprises no primer layer.
 11. A process for the manufacture of aprintable film, comprising the steps of: coating at least one side of asubstrate having two sides with an aqueous dispersion comprising thecoating composition of claim 1; and drying the aqueous dispersion toform a dried coating, wherein the printable film comprises no primerlayer.
 12. A process for the manufacture of a printed film, comprisingthe steps of: coating at least one side of a substrate having two sideswith an aqueous dispersion comprising the coating composition of claim1; drying the aqueous dispersion to form a dried coating; inking thedried coating with a radiation curable ink; and curing the ink with UVor EB radiation, wherein the printable film comprises no primer layer.13. The process according to claim 12, wherein the ink is applied to thedried coating after the dried coating has been supplied on to a printingstation.